CN116625219B - Distance monitoring method and system for insulator string of electric power iron tower - Google Patents
Distance monitoring method and system for insulator string of electric power iron tower Download PDFInfo
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Abstract
The invention relates to the technical field of electric power iron tower monitoring, and provides a method and a system for monitoring the distance between insulator strings of an electric power iron tower, wherein the method comprises the following steps: a first monitoring station, a second monitoring station and a third monitoring station are respectively arranged on the substrates of the adjacent power towers; a base station is arranged near the electric iron tower; establishing an overall coordinate system by taking a base station as an origin; establishing a local coordinate system by using the first monitoring station, the second monitoring station and the third monitoring station; obtaining the relation between two insulator strings of adjacent electric power towers; simultaneously, the coordinates of insulator strings on adjacent electric power towers in a local coordinate system of the electric power towers are respectively obtained; respectively obtaining coordinates of insulator strings of adjacent electric power towers in an integral coordinate system; and obtaining the distance between two insulator strings of the adjacent power towers. The distance of insulator chain between the adjacent electric power iron tower can be effectively monitored to this scheme to can judge the body of a tower deformation condition.
Description
Technical Field
The invention relates to the technical field of electric power iron tower monitoring, in particular to a method and a system for monitoring the distance between insulator strings of an electric power iron tower.
Background
The stability of the tower body of the electric power iron tower is an important premise for guaranteeing the safe operation of the power transmission line, particularly in some coal mine goafs, the frequent foundation of the electric power iron tower is unevenly settled, the iron tower is easy to incline, even the tower body is yielding, so that the wire is broken, the electric power accident and the like are caused, and therefore, the distance between adjacent electric power iron tower insulator strings is required to be monitored in real time, and the health state of the electric power iron tower is early warned.
At present, a conventional method for detecting the running state of an iron tower in a power transmission line is manual cycle inspection, and the method cannot monitor the state of the iron tower in the running process in real time. With the development of the internet of things technology, people gradually propose to monitor the attitude of an iron tower by adopting a wireless sensor so as to solve the problem of monitoring real-time performance, and patent publication No. CN110763271A (Beidou satellite railway iron tower monitoring device and method) proposes to realize inclination monitoring, tower foundation settlement monitoring and iron tower environment monitoring on a railway iron tower by adopting a Beidou satellite-based accurate positioning mode; patent publication No. CN109737922A, "a communication tower monitoring device and method", proposes to monitor the tilt of the tower with a gyroscope and provide a correction method for the data null shift of the gyroscope. These solutions focus on the attitude monitoring of the pylon, but no effective means are found in the current patents for the distance monitoring between adjacent pylon insulator strings and pylon deformation conditions.
Therefore, there is a need to develop a method and a system for monitoring the distance between insulator strings of power towers, which can effectively monitor the distance between insulator strings of adjacent power towers and judge the deformation condition of the tower body.
Disclosure of Invention
The invention aims to provide a distance monitoring method and a distance monitoring system for an insulator string of an electric power iron tower, which solve the problem that the distance between adjacent electric power iron towers cannot be monitored, and can monitor the distance of the insulator string and judge the deformation condition of a tower body.
In order to solve the technical problems, as one aspect of the present invention, there is provided a method for monitoring a distance between insulator strings of an electronic iron tower, comprising the steps of:
the base that sets up the monitoring station respectively at adjacent electric power iron tower, every electric power iron tower is provided with the monitoring station more than 3, and the monitoring station includes: the first monitoring station, the second monitoring station and the third monitoring station are connected with each other in a mode that the connecting line of the first monitoring station and the second monitoring station is perpendicular to the connecting line of the first monitoring station and the third monitoring station; taking a first monitoring station as an origin of a local coordinate system; a base station is arranged near the electric iron tower;
establishing an overall coordinate system by taking a base station as an origin;
establishing a local coordinate system by using the first monitoring station, the second monitoring station and the third monitoring station;
obtaining the relation between two adjacent insulator strings of the electric power iron tower according to the coordinates of the origin of the local coordinate system in the integral coordinate system and the directional cosine of the local coordinate system in the integral coordinate system; simultaneously, the coordinates of insulator strings on adjacent electric power towers in a local coordinate system of the electric power towers are respectively obtained;
according to the relation between two insulator strings of adjacent power towers and the coordinates of the insulator strings on the adjacent power towers in the local coordinate system of the power towers, the coordinates of the insulator strings of the adjacent power towers in the integral coordinate system are obtained respectively;
and obtaining the distance between the two insulator strings of the adjacent power towers according to the coordinates of the insulator strings of the adjacent power towers in the integral coordinate system.
As an example embodiment of the present invention, the method for monitoring the distance between the insulator strings of the electronic iron tower further includes:
after obtaining the distance between two insulator strings of adjacent line towers, calculating the inclination change value of the tower body, and if the inclination change of the tower body is smaller than or equal to a specified threshold value, the distance is effective; otherwise the distance is not valid.
The method for calculating the gradient change value of the tower body adopts the formula 1:
equation 1;
where abs represents the absolute value;indicating the initial moment +.>Cosine of direction and monitoring moment->An angle of cosine of the direction; />Representing the change value of the tower body inclination from the initial moment to the monitoring moment; k represents a specified threshold; />The direction represents a direction perpendicular to a plane in which the first monitoring station, the second monitoring station and the third monitoring station are located.
As an example embodiment of the present invention,the calculation method of (1) adopts the formula 2:
equation 2;
wherein ,indicating the initial moment +.>Cosine of the direction; />Indicating monitoring time +.>Cosine of the direction.
As an example embodiment of the present invention, the tower inclination change value is obtained by monitoring according to an inclination angle monitor provided on the electric iron tower.
As an exemplary embodiment of the present invention, the method for respectively obtaining the relationship between the local coordinate system and the global coordinate system of the adjacent power towers uses formula 3:
equation 3;
wherein ,PA The coordinates of the insulator string in a local coordinate system; p (P) B The coordinates of the insulator string in the integral coordinate system; t represents a translation homogeneous transformation matrix; r represents a rotation homogeneous transformation matrix.
As an example embodiment of the present invention,
;/>;
wherein ,is->Cosine of the direction; />Is->Cosine of the direction; />Is->Cosine of the direction; coordinates O' (x) of the local coordinate system origin in the global coordinate system 0 ,y 0 ,z 0 );/>The direction indicates the direction from the first monitoring site to the second monitoring site, +.>Indicating the direction of the first to the third monitoring station, < >>The direction represents a direction perpendicular to a plane in which the first monitoring station, the second monitoring station and the third monitoring station are located.
As an example embodiment of the present invention,
=/>=
;
=/>=
;
;
wherein the second monitoring station has a coordinate (x 1 ,y 1 ,z 1 ) The method comprises the steps of carrying out a first treatment on the surface of the The third monitoring station has a coordinate (x 2 ,y 2 ,z 2 )。
As an example embodiment of the present invention, the method for obtaining the distance between two insulator strings of adjacent power towers according to the coordinates of the insulator strings of adjacent power towers in the global coordinate system uses equation 4:
equation 4;
wherein L represents the distance between two insulator strings of adjacent power towers, and the coordinates of the insulator string of one power tower in the whole coordinate system areThe insulator string of the other electric iron tower has a coordinate of +.>。
As a second aspect of the present invention, the present invention provides a distance monitoring system for an insulator string of an electric iron tower, comprising: a plurality of monitoring stations, a base station and a data processing device;
the substrates of two adjacent electric power towers are respectively provided with a first monitoring station, a second monitoring station and a third monitoring station; the connecting line of the first monitoring station and the second monitoring station is perpendicular to the connecting line of the first monitoring station and the third monitoring station;
the base station is arranged near the electric iron tower;
the data processing device is connected with the plurality of monitoring stations and the base station in a communication manner; the distance between two insulator strings of the adjacent power towers is calculated; the data processing device establishes an overall coordinate system by taking a base station as an origin, and takes a first monitoring station as the origin of a local coordinate system; establishing a local coordinate system by using the first monitoring station, the second monitoring station and the third monitoring station; respectively acquiring the relation between a local coordinate system and a global coordinate system of the adjacent electric power iron towers; respectively acquiring coordinates of insulator strings on adjacent electric power towers in a local coordinate system of the electric power towers; respectively obtaining the coordinates of the insulator strings of the adjacent electric power towers in the integral coordinate system according to the relation between the local coordinate system and the integral coordinate system of the adjacent electric power towers and the coordinates of the insulator strings of the adjacent electric power towers in the local coordinate system of the electric power towers; and obtaining the distance between the two insulator strings of the adjacent power towers according to the coordinates of the insulator strings of the adjacent power towers in the integral coordinate system.
As an example embodiment of the present invention, the power tower insulator string distance monitoring system further includes an inclination monitor communicatively connected to the data processing device for monitoring a tower body inclination variation value of the power tower.
The beneficial effects of the invention are as follows:
according to the invention, GNSS is adopted to monitor the distance between adjacent electric power towers, the deformation condition of the tower body can be judged, the health state of the electric power towers can be early warned, and the safe performance of electric power transmission is ensured.
Drawings
FIG. 1 schematically illustrates a schematic of a monitoring station placed on an electric pylon;
fig. 2 schematically shows a step diagram of a method for monitoring the distance between insulator strings of an electric iron tower.
The system comprises a BD01, a first monitoring station, a BD02, a second monitoring station, a BD03, a third monitoring station, a QJ01, a first inclination angle monitor, a QJ02 and a second inclination angle monitor.
Detailed Description
Example embodiments will now be described more fully with reference to the accompanying drawings. However, the exemplary embodiments can be embodied in many forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the example embodiments to those skilled in the art. In the drawings, the thickness of regions and layers are exaggerated for clarity. The same reference numerals in the drawings denote the same or similar structures, and thus detailed descriptions thereof will be omitted.
The described features, structures, or characteristics may be combined in any suitable manner in one or more embodiments. In the following description, numerous specific details are provided to give a thorough understanding of embodiments of the invention. One skilled in the relevant art will recognize, however, that the invention may be practiced without one or more of the specific details, or with other methods, components, materials, etc. In other instances, well-known structures, materials, or operations are not shown or described in detail to avoid obscuring aspects of the invention.
The following examples describe the tape laying apparatus and the tape laying method of the series battery cells of the present invention, but the present invention is not limited to these examples. All other embodiments, which can be made by those skilled in the art without the inventive effort, are intended to be encompassed within the scope of the present invention.
As a first embodiment of the present invention, there is provided a distance monitoring system for an insulator string of an electric power pylon, including: a plurality of monitoring stations, a base station and a data processing device.
The bases of two adjacent electric power towers are respectively provided with a first monitoring station BD01, a second monitoring station BD02 and a third monitoring station BD03. The line connecting the first monitoring station BD01 and the second monitoring station BD02 is perpendicular to the line connecting the first monitoring station BD01 and the third monitoring station BD03. Preferably, the monitoring station is a Beidou monitoring station.
The base station is arranged near the electric iron tower. Preferably, the base station adopts a Beidou base station.
The data processing device is connected with the plurality of monitoring stations and the base station in a communication manner; the distance between two insulator strings of the adjacent power towers is calculated; the data processing device establishes an overall coordinate system by taking a base station as an origin, and takes a first monitoring station BD01 as the origin of a local coordinate system; establishing a local coordinate system by using a first monitoring station BD01, a second monitoring station BD02 and a third monitoring station BD 03; respectively acquiring the relation between a local coordinate system and a global coordinate system of the adjacent electric power iron towers; respectively acquiring coordinates of insulator strings on adjacent electric power towers in a local coordinate system of the electric power towers; respectively obtaining the coordinates of the insulator strings of the adjacent electric power towers in the integral coordinate system according to the relation between the local coordinate system and the integral coordinate system of the adjacent electric power towers and the coordinates of the insulator strings of the adjacent electric power towers in the local coordinate system of the electric power towers; and obtaining the distance between the two insulator strings of the adjacent power towers according to the coordinates of the insulator strings of the adjacent power towers in the integral coordinate system.
The electric power iron tower insulator chain distance monitoring system further comprises an inclination angle monitor which is connected with the data processing device in a communication mode and used for monitoring the tower body inclination change value of the electric power iron tower. The deformation condition of the electric power iron tower can be obtained according to the inclination change value of the tower body, and if the deformation condition is overlarge, the monitored distance between the two insulator strings is invalid. Preferably, the tilt monitor comprises a first tilt monitor and a second tilt monitor, the tilt monitors being triaxial tilt meters.
Through the system of this scheme, can calculate the deformation condition of distance monitoring and iron tower between the adjacent iron tower insulator chain.
As a second embodiment of the present invention, the present invention provides a method for monitoring a distance between insulator strings of an electronic iron tower, using the distance monitoring system for an electronic iron tower insulator string of the first embodiment, as shown in fig. 2, comprising the steps of:
the base that sets up the monitoring station respectively at adjacent electric power iron tower, every electric power iron tower is provided with the monitoring station more than 3, and the monitoring station includes: the first monitoring station BD01, the second monitoring station BD02 and the third monitoring station BD03, wherein the connecting line of the first monitoring station BD01 and the second monitoring station BD02 is perpendicular to the connecting line of the first monitoring station BD01 and the third monitoring station BD 03; the first monitoring station BD01 is used as an origin of a local coordinate system; a base station is arranged near the electric iron tower.
S1: and establishing an overall coordinate system by taking the base station as an origin.
S2: a local coordinate system is established with the first monitoring station BD01, the second monitoring station BD02, and the third monitoring station BD03.
The origin of the local coordinate system is a first monitoring station BD01, and the local coordinate system is formed by constructing a plane formed by the first monitoring station BD01, a second monitoring station BD02 and a third monitoring station BD03 and a normal vector of the plane. Principal vector in X-axis direction of local coordinate systemThe Y-axis direction is the main vector +.>The direction from the first monitoring station BD01 to the third monitoring station BD03 is the Z-axis direction, namely the main vector +.>The normal vector of the plane formed by the first monitoring station BD01, the second monitoring station BD02 and the third monitoring station BD03 is also a direction perpendicular to the plane where the first monitoring station BD01, the second monitoring station BD02 and the third monitoring station BD03 are located.
S3: obtaining the relation between two adjacent insulator strings of the electric power iron tower according to the coordinates of the origin of the local coordinate system in the integral coordinate system and the directional cosine of the local coordinate system in the integral coordinate system; simultaneously, the coordinates of insulator strings on adjacent electric power towers in a local coordinate system of the electric power towers are respectively obtained.
The monitoring station is communicatively connected to the base station, and the base station can obtain location information of the monitoring station. The base station (Beidou monitoring station) can acquire the coordinates (x) of the origin of the local coordinate system in the whole coordinate system 0 ,y 0 ,z 0 ) Three principal vectors of a local coordinate system、/>、/>The direction cosine in the global coordinate system. The distance problem of the two insulator strings to be solved is converted into the coordinate conversion problem from the local coordinate system to the whole coordinate system, and the distance can be directly solved as long as the coordinates of each insulator string in the whole coordinate system are known.
Therefore, a relation up to the local coordinate system and the global coordinate system is required.
Under the global coordinate system: the global coordinate system origin O (0, 0), the local coordinate system origin, i.e., the coordinates of the first monitoring station BD01, are (x) 0 ,y 0 ,z 0 ) Second monitoringThe coordinates of the station BD02 and the third monitoring station BD03 are (x 1 ,y 1 ,z 1 )、(x 2 ,y 2 ,z 2 )。
Local coordinate systemDirection cosine of (2)>=/>=
;
Direction cosine of (2)>=/>=
;
Is the directional cosine of (2)
。
Assume that the local coordinate of a certain insulator string on an iron tower isFor homogeneous->The overall coordinates are +.>For homogeneous->It is now necessary to convert the local coordinates to global coordinates.
Coordinate transformation is classified into translation coordinate transformation and rotation transformation. Translation homogeneous transformation matrixRotating the homogeneous transformation matrix->,/>Combined by matrix multiplication;
Thus, there are:
。
from the above analysis, the method for obtaining the relationship between the local coordinate system and the global coordinate system of the adjacent power towers respectively uses formula 3:
equation 3;
wherein ,PA The coordinates of the insulator string in a local coordinate system; p (P) B The coordinates of the insulator string in the integral coordinate system; t represents a translation homogeneous transformation matrix; r represents a rotation homogeneous transformation matrix.
;/>;
wherein ,is->Cosine of the direction; />Is->Cosine of the direction; />Is->Cosine of the direction; coordinates O' (x) of the local coordinate system origin in the global coordinate system 0 ,y 0 ,z 0 );/>The direction indicates the direction of the first monitoring station BD01 to the second monitoring station BD02, +.>Indicates the direction from the first monitoring station BD01 to the third monitoring station BD03, +.>The direction indicates a direction perpendicular to the plane in which the first monitoring station BD01, the second monitoring station BD02, and the third monitoring station BD03 are located.
wherein ,
=/>=
;
=/>=
;
;
wherein the coordinates of the second monitoring station BD02 in the global coordinate system are (x) 1 ,y 1 ,z 1 ) The method comprises the steps of carrying out a first treatment on the surface of the The coordinates of the third monitoring station BD03 in the global coordinate system are (x 2 ,y 2 ,z 2 )。
The coordinates of the insulator string on the iron tower in the local coordinate system can be obtained through means of iron tower design drawings, unmanned aerial vehicle photogrammetry modeling, total station measurement and the like.
S4: and respectively obtaining the coordinates of the insulator strings of the adjacent electric power towers in the whole coordinate system according to the relation between the two insulator strings of the adjacent electric power towers and the coordinates of the insulator strings of the adjacent electric power towers in the local coordinate system of the electric power towers.
S5: and obtaining the distance between the two insulator strings of the adjacent power towers according to the coordinates of the insulator strings of the adjacent power towers in the integral coordinate system.
The method for obtaining the distance between two insulator strings of the adjacent power iron towers according to the coordinates of the insulator strings of the adjacent power iron towers in the integral coordinate system adopts the formula 4:
equation 4;
wherein L represents the distance between two insulator strings of adjacent power towers, and the coordinates of the insulator string of one power tower in the whole coordinate system areThe insulator string of the other electric iron tower has a coordinate of +.>。
S6: calculating a tower inclination change value, and if the tower inclination change is smaller than or equal to a specified threshold value, enabling the distance to be effective; otherwise the distance is not valid.
The method for calculating the gradient change value of the tower body adopts the formula 1:
equation 1;
where abs represents the absolute value;indicating the initial moment +.>Cosine of direction and monitoring moment->An angle of cosine of the direction; />Representing the change value of the tower body inclination from the initial moment to the monitoring moment; k represents a specified threshold; />The direction indicates a direction perpendicular to the plane in which the first monitoring station BD01, the second monitoring station BD02, and the third monitoring station BD03 are located.
The initial moment represents the moment when the tilt meter is mounted on the tower body, i.e. the moment when the tilt meter device data is on line.
The calculation method of (1) adopts the formula 2:
equation 2;
wherein ,indicating the initial moment +.>Cosine of the direction; />Indicating monitoring time +.>Cosine of the direction.
The inclination change value of the tower body is obtained by monitoring according to an inclination angle monitor arranged on the electric iron tower. Preferably, two tilt monitors are provided in order to prevent one of them from being taken off-line due to the harsh environment surrounding the power pylon.
And judging whether the monitoring result is reasonable or not according to the comparison of the inclination change value of the tower body and the designated threshold value, and if the inclination change value of the tower body is large, indicating that the iron tower has large deformation and checking the field condition of the iron tower. The K value is set according to the structural characteristics of the iron tower, specific conditions and the like.
According to the invention, GNSS is adopted to monitor the distance between adjacent electric power towers, the deformation condition of the tower body can be judged, the health state of the electric power towers can be early warned, and the safe performance of electric power transmission is ensured.
The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
Claims (10)
1. The method for monitoring the distance between the insulator strings of the electric power iron tower is characterized by comprising the following steps of:
the method comprises the steps that monitoring stations are respectively arranged on bases of adjacent power towers, each power tower is provided with more than 3 monitoring stations, each monitoring station comprises a first monitoring station, a second monitoring station and a third monitoring station, and the connecting line of the first monitoring station and the second monitoring station is perpendicular to the connecting line of the first monitoring station and the third monitoring station; taking a first monitoring station as an origin of a local coordinate system; a base station is arranged near the electric iron tower;
establishing an overall coordinate system by taking a base station as an origin;
establishing a local coordinate system by using the first monitoring station, the second monitoring station and the third monitoring station;
obtaining the relation between two adjacent insulator strings of the electric power iron tower according to the coordinates of the origin of the local coordinate system in the integral coordinate system and the directional cosine of the local coordinate system in the integral coordinate system; simultaneously, the coordinates of insulator strings on adjacent electric power towers in a local coordinate system of the electric power towers are respectively obtained;
according to the relation between two insulator strings of adjacent power towers and the coordinates of the insulator strings on the adjacent power towers in the local coordinate system of the power towers, the coordinates of the insulator strings of the adjacent power towers in the integral coordinate system are obtained respectively;
and obtaining the distance between the two insulator strings of the adjacent power towers according to the coordinates of the insulator strings of the adjacent power towers in the integral coordinate system.
2. The method for monitoring the distance of an insulator string of a power tower according to claim 1, further comprising:
after the distance between two adjacent insulator strings of the electric power iron tower is obtained, calculating the inclination change value of the tower body, and if the inclination change value of the tower body is smaller than or equal to a specified threshold value, the distance is effective; otherwise the distance is not valid.
3. The method for monitoring the distance between the insulator strings of the electric power iron tower according to claim 2, wherein the method for calculating the inclination change value of the tower body adopts the formula 1:
equation 1;
where abs represents the absolute value;indicating the initial moment +.>Cosine of direction and monitoring moment->An angle of cosine of the direction; />Representing the change value of the tower body inclination from the initial moment to the monitoring moment; k represents a specified threshold; />The direction represents a direction perpendicular to a plane in which the first monitoring station, the second monitoring station and the third monitoring station are located.
4. The method for monitoring the distance between the insulator strings of the electric iron tower according to claim 3,the calculation method of (1) adopts the formula 2:
equation 2;
wherein ,indicating the initial moment +.>Cosine of the direction; />Indicating monitoring time +.>Cosine of the direction.
5. A method for monitoring the distance between insulator strings of a power tower according to claim 3, wherein the change value of the inclination of the tower body is obtained by monitoring according to an inclination angle monitor arranged on the power tower.
6. The method for monitoring the distance between the insulator strings of the electric power iron towers according to claim 1, wherein the method for respectively obtaining the relation between the local coordinate system and the whole coordinate system of the adjacent electric power iron towers adopts the formula 3:
equation 3;
wherein ,PA The coordinates of the insulator string in a local coordinate system; p (P) B The coordinates of the insulator string in the integral coordinate system; t represents a translation homogeneous transformation matrix; r represents a rotation homogeneous transformation matrix.
7. The method for monitoring the distance between the insulator strings of the electric iron tower according to claim 6, wherein,
;/>;
wherein ,is->Surplus of directionA chord; />Is->Cosine of the direction;is->Cosine of the direction; coordinates O' (x) of the local coordinate system origin in the global coordinate system 0 ,y 0 ,z 0 );/>The direction indicates the direction from the first monitoring site to the second monitoring site, +.>Indicating the direction of the first to the third monitoring station, < >>The direction represents a direction perpendicular to a plane in which the first monitoring station, the second monitoring station and the third monitoring station are located.
8. The method for monitoring the distance between the insulator strings of the electric iron tower according to claim 7, wherein,
=/>=
;
=/>=
;
;
wherein the second monitoring station has a coordinate (x 1 ,y 1 ,z 1 ) The method comprises the steps of carrying out a first treatment on the surface of the The third monitoring station has a coordinate (x 2 ,y 2 ,z 2 )。
9. The method for monitoring the distance between two insulator strings of adjacent power towers according to the coordinate of the insulator strings of adjacent power towers in the integral coordinate system according to the claim 1, wherein the method for obtaining the distance between the two insulator strings of adjacent power towers is characterized by adopting the formula 4:
equation 4;
wherein L represents the distance between two insulator strings of adjacent power towers, and the coordinates of the insulator string of one power tower in the whole coordinate system areThe coordinates of the insulator string of the other electric iron tower in the integral coordinate system are。
10. Electric power iron tower insulator chain distance monitoring system, characterized in that includes: a plurality of monitoring stations, a base station and a data processing device;
the substrates of two adjacent electric power towers are respectively provided with a first monitoring station, a second monitoring station and a third monitoring station; the connecting line of the first monitoring station and the second monitoring station is perpendicular to the connecting line of the first monitoring station and the third monitoring station;
the base station is arranged near the electric iron tower;
the data processing device is connected with the plurality of monitoring stations and the base station in a communication manner; the distance between two insulator strings of the adjacent power towers is calculated; the data processing device establishes an overall coordinate system by taking a base station as an origin, and takes a first monitoring station as the origin of a local coordinate system; establishing a local coordinate system by using the first monitoring station, the second monitoring station and the third monitoring station; respectively acquiring the relation between a local coordinate system and a global coordinate system of the adjacent electric power iron towers; respectively acquiring coordinates of insulator strings on adjacent electric power towers in a local coordinate system of the electric power towers; respectively obtaining the coordinates of the insulator strings of the adjacent electric power towers in the integral coordinate system according to the relation between the local coordinate system and the integral coordinate system of the adjacent electric power towers and the coordinates of the insulator strings of the adjacent electric power towers in the local coordinate system of the electric power towers; and obtaining the distance between the two insulator strings of the adjacent power towers according to the coordinates of the insulator strings of the adjacent power towers in the integral coordinate system.
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